Bit-flip errors in dissipative cat qubits: second-order perturbation theory

TL;DR

This paper develops a second-order perturbation theory for dissipative cat qubits to accurately predict the exponentially suppressed bit-flip rates caused by various perturbations, resolving previous discrepancies between theory and experiment.

Contribution

It introduces a second-order perturbation framework on nonlinear Lindbladians to analytically estimate bit-flip rates in dissipative cat qubits, aligning theory with numerical results.

Findings

Analytical expression for bit-flip rate due to single-photon loss

Good agreement between theory and numerical simulations

Extension of the method to frequency detuning and Z gate perturbations

Abstract

Dissipative cat qubits are known for the exponential suppression of the bit-flip rate. However, there is significant discrepancy between experimental measurements and analytical predictions of the strength of the bit-flip suppression. In this paper we resolve this discrepancy for some of the perturbations, by developing a second-order perturbation theory on top of a nonlinear dissipative Lindbladian. Following this scheme, we derive an analytical expression for the exponentially small bit-flip rate due to single-photon loss, which shows good agreement with numerical simulations. We also apply our scheme to other perturbations, such as frequency detuning and the Z gate, and find the corresponding bit-flip rates, which also show good agreement with the numerical simulation.